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由铁和2-氧代戊二酸依赖性加氧酶LolO介导的洛里菌素醚桥的形成:连续羟基化和氧环化反应的区域化学和立体化学

Installation of the Ether Bridge of Lolines by the Iron- and 2-Oxoglutarate-Dependent Oxygenase, LolO: Regio- and Stereochemistry of Sequential Hydroxylation and Oxacyclization Reactions.

作者信息

Pan Juan, Bhardwaj Minakshi, Zhang Bo, Chang Wei-Chen, Schardl Christopher L, Krebs Carsten, Grossman Robert B, Bollinger J Martin

机构信息

Department of Chemistry and Department of Biochemistry and Molecular Biology , The Pennsylvania State University , University Park , Pennsylvania 16802 , United States.

出版信息

Biochemistry. 2018 Apr 10;57(14):2074-2083. doi: 10.1021/acs.biochem.8b00157. Epub 2018 Mar 29.

DOI:10.1021/acs.biochem.8b00157
PMID:29537853
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5895980/
Abstract

The core of the loline family of insecticidal alkaloids is the bicyclic pyrrolizidine unit with an additional strained ether bridge between carbons 2 and 7. Previously reported genetic and in vivo biochemical analyses showed that the presumptive iron- and 2-oxoglutarate-dependent (Fe/2OG) oxygenase, LolO, is required for installation of the ether bridge upon the pathway intermediate, 1- exo-acetamidopyrrolizidine (AcAP). Here we show that LolO is, in fact, solely responsible for this biosynthetic four-electron oxidation. In sequential 2OG- and O-consuming steps, LolO removes hydrogens from C2 and C7 of AcAP to form both carbon-oxygen bonds in N-acetylnorloline (NANL), the precursor to all other lolines. When supplied with substoichiometric 2OG, LolO only hydroxylates AcAP. At higher 2OG:AcAP ratios, the enzyme further processes the alcohol to the tricyclic NANL. Characterization of the alcohol intermediate by mass spectrometry and nuclear magnetic resonance spectroscopy shows that it is 2- endo-hydroxy-1- exo-acetamidopyrrolizidine (2- endo-OH-AcAP). Kinetic and spectroscopic analyses of reactions with site-specifically deuteriated AcAP substrates confirm that the C2-H bond is cleaved first and that the responsible intermediate is, as expected, an Fe-oxo (ferryl) complex. Analyses of the loline products from cultures fed with stereospecifically deuteriated AcAP precursors, proline and aspartic acid, establish that LolO removes the endo hydrogens from C2 and C7 and forms both new C-O bonds with retention of configuration. These findings delineate the pathway to an important class of natural insecticides and lay the foundation for mechanistic dissection of the chemically challenging oxacyclization reaction.

摘要

杀虫生物碱洛林家族的核心是双环吡咯里西啶单元,在碳2和碳7之间还有一个额外的张力醚桥。先前报道的遗传遗传和体内生化分析表明,推测的铁和2-氧代戊二酸依赖性(Fe/2OG)加氧酶LolO,是在途径中间体1-外乙酰氨基吡咯里西啶(AcAP)上安装醚桥所必需的。在这里,我们表明LolO实际上是这种生物合成四电子氧化的唯一负责者。在连续消耗2OG和O的步骤中,LolO从AcAP的C2和C7去除氢,以在N-乙酰去甲洛林(NANL)中形成两个碳-氧键,NANL是所有其他洛林的前体。当提供亚化学计量的2OG时,LolO仅将AcAP羟基化。在较高的2OG:AcAP比率下,该酶进一步将醇加工成三环NANL。通过质谱和核磁共振光谱对醇中间体的表征表明它是2-内羟基-1-外乙酰氨基吡咯里西啶(2-内-OH-AcAP)。与位点特异性氘代AcAP底物反应的动力学和光谱分析证实,C2-H键首先断裂,并且如预期的那样,负责的中间体是铁-氧(高铁)配合物。对用立体特异性氘代AcAP前体、脯氨酸和天冬氨酸喂养的培养物中的洛林产物进行分析,确定LolO从C2和C7去除内氢,并在构型保留的情况下形成两个新的C-O键。这些发现描绘了一类重要天然杀虫剂的合成途径,并为对具有化学挑战性的氧环化反应进行机理剖析奠定了基础。

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